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Title page for ETD etd-03312008-182826

Type of Document

Dissertation

Author

Garbarini, Nicole Jodela

URN

etd-03312008-182826

Title

Regulation of the neuronal K+-Cl- cotransporter KCC2 by protein associated with MYC

Degree

PhD

Department

Neuroscience

Advisory Committee

Advisor Name

Title

Randy Blakely

Committee Chair

Anne Kenworthy

Committee Member

Bih-Hwa Shieh

Committee Member

Eric Delpire

Committee Member

Louis DeFelice

Committee Member

Keywords

Carrier proteins -- Molecular aspects

Protein-protein interactions

chloride

cotransport

KCC2

PAM

PHR1

RCC1

Chlorides -- Physiological transport

Nerve tissue proteins -- Molecular aspects

Date of Defense

2008-01-23

Availability

unrestricted

Abstract

The neuron-specific electroneutral potassium (K+) and chloride (Cl-) cotransporter, KCC2, is a key regulator of neuronal Cl-. KCC2 has been shown to play a critical role in controlling neuronal excitability, yet little is known about its regulation. Protein-protein interactions are generally well known to provide insight into membrane transporter regulation. Therefore, I have chosen to identify novel KCC2 protein-protein interactions, with the goal of studying how these interactions affect KCC2 activity.

I performed a yeast-two hybrid screen of a mouse brain cDNA library and identified several novel binding partners of the carboxyl terminus of KCC2 (KCC2-CT). One of these identified binding partners is Protein Associated with Myc, or PAM. Binding between KCC2 and the RCC1 domain of PAM (RCC1/PAM) was demonstrated using yeast two-hybrid, GST-pull-down assay, and coimmunoprecipitation. In order to study the functional role of PAM binding to KCC2, I identified the binding site of RCC1/PAM on the KCC2-CT, and within this site created a point mutant which disrupts RCC1/PAM binding. This point mutation was then transferred into full-length KCC2 and compared with wild-type KCC2 in 86Rb+/K+ uptake experiments to assess differences in transport activity. These flux experiments, along with experiments to measure changes in RNA and protein levels, lead to the conclusion that PAM binding to KCC2 does not primarily affect K-Cl transport by altering cell-surface expression of the cotransporter. Rather, PAM binding to the carboxyl terminus of KCC2 likely participates in the net dephosphorylation of KCC2, which in turn leads to activation of KCC2-mediated ion transport.